DE19900475A1 - Print image generation using paper with micro capsules - Google Patents

Abstract

The printing process uses a composite paper which has embedded capsules containing inks of different colors that are selectively released. The sheets are fed by a roller (50) over a thermal print head (34), and this has bimetallic elements (Rn) that are selectively activated to apply temperature and pressure to the surface of the paper.

Description

The invention relates to image formation on a substrate by selective squeezing breaking and breaking microcapsules filled with a dye.

An image generation principle of this type is already known. The covers of it microcapsules used consist of a photo-curable resin, and an optical image is formed as a latent image on the microcapsule layer by it is exposed to rays of light that come with a digital sequence of image pixel signals len are modulated. The latent image is then exerted on the Mi developed the capsule layer. The microcapsules that are not exposed to light are crushed and broken, causing the dye to escape and makes the latent image visible in this way.

With this known imaging principle, each substrate must be light-tight be packed, which results in a high cost of materials. Furthermore, the Substrates are handled with care so as not to apply excessive pressure suspend because the unexposed microcapsules are soft, which makes the Dye could leak out undesirably.  

An image forming device is also known, in which an image substrate is provided a microcapsule layer is used, the microcapsules with differ Chen dyes are filled. Here the different colors are selected made visible by exposing them to predetermined temperatures. Nevertheless, a developed color must be determined by exposure to light th wavelength are fixed. This imaging device is expensive because a special radiation device for fixing a developed Color is necessary, which also increases electricity consumption. Because a heating process for color development and an irradiation process to fix each Color is required, this includes rapid color imaging on the substrate out.

It is an object of the invention to provide a system for rapid image generation to indicate costs and without high material costs.

The invention solves this problem by the features of claim 1 or 2. Advantageous further developments are the subject of the subclaims.

The invention is explained in more detail below with reference to the drawings. In this demonstrate:

Fig. 1 shows the cross section of a substrate for image formation with three types of microcapsules as a first embodiment,

Fig. 2 is a graphical representation of the characteristic curve of the Elastizi tätskoeffizienten a synthetic resin with memory effect,

Fig. 3 is a graphical representation of the pressure / temperature refractive char acteristics of the microcapsules according to Fig. 1,

Fig. 4 shows the cross-section of three types of microcapsules having different wall thicknesses,

Krokapselart Fig. 5 is a view similar to FIG. 1 for the selective breaking of an Mi,

Fig. 6 shows the cross section of an image generating device for the system shown in Fig. 1 substrate,

Fig. 7 is a partial perspective view of a thermal printing head,

Fig. 8 elements the cross-section of a pressure roller and a bent bimetallic strip,

Fig. 9 is a view similar to FIG. 8,

Fig. 10 is a view similar to FIG. 8,

Fig. 11 is a block diagram of a control circuit of the image forming device shown in Fig. 6,

Fig an AND circuit berschaltung. 12 with a transistor in a printhead Trei,

Fig. 13 shows a part of a flowchart for a printing operation in an image forming apparatus,

Fig. 14 is a further part of the flow chart of the printing operation,

Fig. 15 is a timing diagram for a pulse signal and a control signal to control the print head driving circuit for a cyan image point,

Fig. 16 is a time chart similar to FIG. 15 for a magenta image point,

Fig. 17 is a time chart similar to FIG. 15 for a yellow image point,

Fig. 18 shows the cross section of a substrate with a layer of microcapsules with three types of microcapsules as a further embodiment,

Fig. 19 is a graphical representation of the pressure / temperature refractive char acteristics of the microcapsule type shown in Fig. 18,

Fig. 20 is a modification of the in Fig. 11 block diagram shown for color image forming with a substrate of the type shown in Fig. 18,

Fig. 21 shows a part of a flowchart for a printing operation with the substrate of FIG. 18,

Figure 22 is a further part. Of the flow chart,

Fig. 23 is a table showing the relationship of image pixel signals three primary colors and a control signal, and

Figure 24 is a timing diagram of a pulse signal and a control signal for a printhead driver circuit.

Fig. 1 shows a substrate 10 which is used in a first embodiment of an image forming device. The substrate 10 consists of a paper sheet 12 , a microcapsule layer 14 and a transparent protective film 16 thereon.

The microcapsule layer 14 contains three types of microcapsules: first microcapsules 18 C with cyan dye, second microcapsules 18 M with magenta dye and third microcapsules 18 Y with yellow dye. These microcapsules 18 C, 18 M and 18 Y are evenly distributed in the microcapsule layer 14 . Each type of microcapsule contains microcapsules with a synthetic resin shell that is usually white. Furthermore, the microcapsules 18 C, 18 M, 18 Y can be produced by a known polymerization process, such as boundary layer polymerization, in-situ polymerization or the like, and then have an average diameter of a few microns, e.g. B. 5 microns to 10 microns.

If the paper sheet 12 contains a single pigment dye, the synthetic resin material of the microcapsules 18 C, 18 M and 18 Y can contain the same pigment.

In order to form the microcapsule layer 14 uniformly, equal proportions of the cyan, magenta and yellow microcapsules 18 C, 18 M and 18 Y are homogeneously mixed with a binder solution to form a suspension, and the paper sheet 12 is coated with the binder solution, which then contains the microcapsules 18 C, 18 M and 18 Y. An atomizer is used for this.

In Fig. 1, the microcapsule layer 14 is shown with a thickness corresponding to the diameter of the microcapsules 18 C, 18 M and 18 Y. However, the microcapsules are also one above the other, so that the microcapsule layer 14 has a greater thickness than a microcapsule diameter.

In the exemplary embodiment shown in FIG. 1, a synthetic resin with a memory effect is used for each type of microcapsule. Such a material is e.g. B. Polyure thankunstharz such as polynorbornene, trans-1,4-polyisoprene polyurethane. Other such synthetic resins such as polyimide resins, polyamide resins, polyvinyl chloride resins, polyester resins, etc. can also be used.

As can be seen from the graph shown in FIG. 2, the synthetic resin has an elicity coefficient which changes abruptly at a glass transition temperature Tg. In the synthetic resin, the Brownian molecular movement is prevented in a low temperature range a below the glass transition temperature Tg, so that the synthetic resin has a glass phase there. On the other hand, the Brownian movement becomes increasingly energetic in a high temperature range b above the glass transition temperature Tg, so that the synthetic resin has a rubber elasticity in this range.

The memory effect of the synthetic resin results from the following property: If a mass of the synthetic resin becomes a in the low temperature range a Object shaped and then he beyond the glass transition temperature Tg heated, the object becomes freely deformable. Then does it get a different shape, this shape is fixed when it cools below the glass transition temperature Tg and maintain. Will it again exceed the glass transition temperature Tg heated without being exposed to any external force, it takes its original shape again.

In the substrate 10 , the memory property per se is not used, but the abrupt change in the coefficient of elasticity is used such that the three types of microcapsules 18 C, 18 M and 18 Y are selectively broken and squeezed at different temperatures and different pressure values.

As the graph shown in Fig. 3 shows, the resin of the cyan micro-capsules 18 C is produced with a characteristic elastic coefficient, the course of which is shown with a solid line over the temperature, for which a glass transition temperature T ₁ applies. The synthetic resin of the magenta microcapsules 18 M has a curve of the elasticity coefficient shown in broken lines and a glass transition temperature T ₂ . The synthetic resin of the yellow microcapsules 18 Y has a double-dash-dotted curve of the elasticity coefficient and a glass transition temperature T ₃ .

Suitable changes in the composition of the synthetic resin and / or suitable selection result in synthetic resins with a memory effect and a glass transition temperature T ₁ , T ₂ and T ₃ .

As shown in FIG. 4, the walls of the microcapsules 18 C, 18 M and 18 Y under schiedliche thicknesses W _C, W _M and W _Y have. The thickness W _C is larger than the thickness W _M and this is larger than the thickness W _Y.

The thickness Wc of the cyan microcapsules 18 C is selected so that each microcapsule is compacted and broken at a pressure between a critical breaking pressure P ₃ and an upper limit pressure P _UL ( FIG. 3) if it has a temperature between the glass transition temperatures T. ₁ and T ₂ . The wall thickness W _{M of} the magenta microcapsules 18 M is chosen so that each microcapsule at a pressure between a critical crushing pressure P ₂ and the critical crushing pressure P ₃ ( FIG. 3) is compacted and broken when it is between a temperature has the glass transition temperatures T ₂ and T ₃ . The wall thickness W _{Y of} the yellow microcapsules 18 Y is selected such that each microcapsule is compacted and broken at a pressure between a critical breaking pressure P ₁ and the critical breaking pressure P ₂ ( FIG. 3) when it reaches a temperature between the glass transition temperature T. ₃ and an upper limit temperature T _UL .

The upper limit pressure P _UL and the upper limit temperature T _UL are selected with due regard to the properties of the synthetic resins used with memory effect.

It follows from this that by suitable selection of a temperature and a breaking pressure for acting on the substrate 10 , selective squeezing and breaking of the types of microcapsules 18 C, 18 M and 18 Y is possible.

Fall the heating temperature and the crushing pressure in the hatched cyan development area C ( Fig. 3), which is defined by temperatures between the glass transition temperatures T ₁ and T ₂ and by pressure values between the critical crushing pressure P ₃ and the upper limit pressure P _UL , only the cyan microcapsules 18 C are crushed and broken, as is shown in FIG. 5 by way of example. If the heating temperature and the pressure fall in the hatched magenta development area M, which is defined by temperatures between the glass transition temperatures T ₂ and T ₃ and pressure values between the critical refractive pressure values P ₂ and P ₃ , then only the magenta microcapsules 18 M bruised and broken. If the heating temperature and the crushing pressure fall within the hatched yellow development area Y, which is defined by temperatures between the glass transition temperature T ₃ and the upper limit pressure P _UL and by pressure values between the critical crushing pressure values P ₁ and P ₂ , only the yellow microcapsules become 18 Y crushed and broken.

Thus, if the heating temperature and the refractive pressure for the substrate 10 are appropriately controlled in accordance with a sequence of digital color image pixel signals, namely digital cyan image pixel signals, digital magenta image pixel signals and digital yellow image pixel signals, then a color image can be generated on the substrate 10 in accordance with these image pixel signals will.

Fig. 6 shows schematically an image forming device which is constructed as a line color printer and generates a color image on the substrate 10 .

The color printer has a rectangular parallelepiped housing 20 with an inlet opening 22 and an outlet opening 24 in the top or a side wall. The substrate 10 is inserted into the housing 20 through the inlet opening 22 and then discharged from the outlet opening 24 after a color image has been formed thereon.

In FIG. 6, the transport of the substrate 10 is shown chain-dotted lines 26. This transport path 26 is defined by a first guide plate 28 , a second guide plate 30 and a third guide plate 32 , which are arranged in the housing 20 at a mutual distance.

The color printer includes a movable thermal printhead assembly 34 below the transport path 26 that can be pivoted between multiple positions.

The thermal print head assembly 34 has an elongated rectangular base plate 36 z. B. made of ceramic with two laterally projecting axle projections 38 . These are aligned with each other along a pivot axis, which is on one of the Längskan th of the base plate 36 , and stored in two bearings, not shown, which are attached to a frame, not shown, of the printer.

As shown in FIG. 6, the base plate 36 is coupled to an electromagnet 40 , the cylinder of which can be pivoted at a point 42 . Its piston is coupled to the base plate 36 near the other longitudinal edge. A stop axis 44 is located close below the guide plate 30 and above the top of the base plate 36 .

The base plate 36 and thus the thermal print head assembly 34 can be pivoted between a first position shown in FIG. 6 and a second position, in which the base plate 34 strikes the stop axis 44 . If the electromagnet 40 is switched off, the thermal print head arrangement 34 is held in the first position. If the electromagnet 40 is switched on, the thermal print head arrangement 34 pivots into the second position.

As shown in FIG. 7, the thermal print head arrangement 34 also contains an arrangement of n resistance elements on its upper side, of which four resistors R ₁ , R ₂ , R ₃ , R ₄ are shown. Each resistor consists of a curved bimetallic element that serves as a pressure / temperature element, as will be described. Only one resistance element R _n can be seen in FIG. 6.

The resistors or bimetallic elements are connected to an integrated driver circuit 46 on the upper side of the base plate 36 and to a common mas connection 48 also connected to the upper side of the base plate 36 . The conductor tracks 46 and 48 can be produced photolithographically.

The color printer also contains a printing roller 50 made of a suitable hard rubber as a printing support, which is arranged so that part of its circumference in the space between the guide plates 30 and 32 is opposite to the arrangement of the n bent bimetallic elements. If the thermal print head arrangement 34 is pivoted from the first into the second position, the bimetal elements R _{n are} pressed against the pressure roller 50 with a predetermined pressure.

In Fig. 6, the thermal print head assembly 34 and the printing roller 50 are shown with a relatively large distance between the bimetal elements R _n and the printing roller 50 at the first position of the thermal print head arrangement 34 for a better overview. The thermal print head arrangement 34 is, however, arranged near the printing roller 50 in such a way that the arrangement of the bimetal elements R _{n is} in contact with the printing roller 50 . The pivoting movement of the thermal print head assembly 34 between the first and the second position is therefore very small.

During a printing operation, the platen roller 50 is rotated intermittently in the direction of arrow A ( Fig. 6) so that the substrate 10 is gradually moved between it and the bimetal elements R _n . During this step movement, a color image is generated line by line on the substrate 10 , and this line printing operation is brought about by pivoting the thermal print head arrangement 34 from the first to the second position. For this purpose, the substrate 10 is introduced into the inlet opening 22 such that the transparent protective film 16 comes into contact with the arrangement of the bimetallic elements R _n .

If no bimetallic element R _{n is} electrically connected, ie it is not heated, then all the bimetallic elements R _n protrude toward the pressure roller 50 with a maximum amount. If a bimetal element R _n is heated by electrical wiring, it is reset. If the thermal print head arrangement 34 is moved from the first to the second position (printing position) after a bimetallic element R _{n has} been heated for a predetermined time, then the pressure exerted with this bimetallic element R _n on the printing roller 50 is lower than that with an unheated one Bimetal element R _n applied pressure.

The thermal printhead assembly 34 is in the printing position, the maximum degree of protrusion of each bimetal element R _{n is set} in the absence of heating so that the pressure exerted on the printing roller is largely equal to the upper limit pressure value P _UL ( Fig. 3).

If the thermal print head assembly 34 is pivoted from the non-printing position after heating up one of the bimetallic elements R _n to a temperature between the glass transition temperatures T ₁ and T ₂ in the printing position, the heated bimetallic element R _n only projects so far that the with him on the pressure roller 50 pressure exerted between the upper limit pressure P _UL and the critical breaking pressure P ₃ ( Fig. 3). If the substrate 10 is between the pressure roller 50 and the arrangement of the bimetallic elements R _n , as shown in FIG. 8, a local area of the microcapsule layer 14 against which the bimetallic element R _{n is} pressed becomes the temperature between the glass transition temperatures T _{n 1} and T ₂ and the pressure between the upper limit pressure value P _UL and the critical breaking pressure P ₃ ( Fig. 3) exposed. As a result, only the cyan microcapsules 18 C are compacted and broken in the local area of the microcapsule layer 14 , so that the cyan dye emerges from them and the local area is developed as a cyan pixel on the microcapsule layer 14 of the substrate 10 .

If the thermal print head assembly 34 from the nonprinting position to heat a bimetallic element R _n to a temperature between the glass transition temperatures T ₂ and is pivoted to the printing position T _3, the degree of protrusion is the heated bimetal element R _n is reduced so that the on the pressure roller 50 thus exerted pressure between the critical crushing pressure values P ₂ and P ₃ ( Fig. 3). If the substrate 10 is between the pressure roller 50 and the arrangement of the bimetallic elements R _n , as shown in FIG. 9, only a local area of the microcapsule layer 14 against which the bimetallic element R _{n concerned is} pressed becomes the temperature between the glass exposed to transition temperatures T ₂ and T ₃ and the pressure between the critical refractive pressure values P ₂ and P ₃ ( FIG. 3). As a result, only the Ma genta microcapsules 18 M are compacted and broken in the local area of the microcapsule layer 14 , as a result of which the magenta dye emerges from them and the local area is developed as a magenta pixel on the microcapsule layer 14 of the substrate 10 .

If the thermal print head assembly 34 to heat from the non-print position on a bimetallic element R _n to a temperature between the glass transition temperatures T ₃ and T ₄ is pivoted to the printing position, the degree of protrusion is the heated bimetal element R _n is reduced so that the resulting pressure exerted on the pressure roller 50 lies between the critical crushing pressure values P ₁ and P ₂ ( FIG. 3). If the substrate 10 is between the pressure roller 50 and the arrangement of the bimetallic elements R _n , as shown in FIG. 10, only a local area of the microcapsule layer 14 against which the bimetallic element R _{n is} pressed is the temperature between the glass transition temperatures T ₃ and T _UL and the pressure between the critical crushing pressure values P ₁ and P ₂ ( Fig. 3) exposed. Thus, only the yellow microcapsules 18 Y are compacted and broken in the local area of the microcapsule layer 14 , so that the yellow dye emerges from them and only the local area is developed as a yellow pixel on the microcapsule layer 14 of the substrate 10 .

In Fig. 6, a control circuit board 52 for controlling the printing operation of the color printer and an electrical power supply 54 for the control circuit board 52 , the electromagnet 40 and the bimetallic elements R _n , etc. are shown.

Fig. 11 shows the block diagram of the control circuit board 52. A printer controller 56 includes a microcomputer. It receives a sequence of digital color image pixel signals from a personal computer or a word processor (not shown) via an interface 58 . The received digital color image pixel signals are then stored in a memory 60 .

The control circuit board 52 also includes a motor driver circuit 62 for an electric motor 64 , e.g. B. a stepper motor, a servo motor or the like, which serves to rotate the printing roller 50 in accordance with a sequence of drive pulses from the motor driver circuit 62 . The output of the drive pulses from the motor driver circuit 62 to the electric motor 64 is controlled by the printer controller 56 .

The control circuit card 52 further includes an electromagnetic driver circuit 66 for the electromagnet 40 ( FIG. 6). The electromagnet 40 is switched on with the driver circuit 66 via the printer controller 56 . As mentioned, the solenoid 40 is normally turned off so that the thermal print head assembly 34 is held in the non-printing position. When the electromagnet 40 is switched on with the driver circuit 66 , the thermal print head arrangement 34 is pivoted from the first into the second position or the print position.

As shown in FIG. 11, the control circuit board 52 further includes a driver circuit 68 which is controlled by the printer controller 56 for selectively turning on the n bimetallic elements R ₁ to R _n . This switching on is controlled with n groups of pulse signals STC and control signals DAG, n groups of pulse signals STM and control signals DAM and n groups of pulse signals STY and control signals DAY, which are output by printer controller 56 to driver circuit 68 corresponding to a line of digital color image pixel signals , namely a single line of digital cyan image pixel signals, a single line of digital magenta image pixel signals and a single line of digital yellow image pixel signals.

The driver circuit 68 contains n groups of AND gates and transistors for the bimetallic elements R ₁ to R _n . In Fig. 12 an AND gate 70 and a transistor 72 are shown as an example for a group. A pulse signal STC, STM or STY and a control signal DAG, DAM or DAY are each supplied to an input of the AND gate 70 by the printer controller 56 . The base of transistor 72 is connected to the output of AND gate 70 . Its collector is connected to the supply voltage V _CC , its emitter is connected to a bimetallic element R _{n assigned to} it.

In Figs. 13 and 14 is the flow chart showing a printing operation of the Druckersteue tion 52 shown for a first embodiment of the printing device. This operation is explained below.

In step 1301 , it is checked whether a single field of color image pixel signals (cyan, magenta, yellow) is stored in the memory 60 . As already stated, a single field of color image pixel signals can be received from a personal computer or a word processor (not shown) via the interface 58 . If the storage of such an individual field is confirmed, control goes to step 1302 , in which the electric motor 64 is actuated in such a way that a substrate 10 is brought into a printing start position.

In step 1303 it is checked whether the substrate 10 has reached the start of printing position, ie whether it is in the printing position. If it is confirmed, control goes to step 1304 and the electric motor 64 is stopped. Then, at step 1305, counters N and L are reset.

In step 1306 , a single line of digital single-color image pixel signals of a first single line of digital color image pixel signals is retrieved from memory 60 with printer controller 56 . Since N = 0 in this state, these digital single-color image pixel signals are assigned to the color cyan. Then, at step 1307, pulse signals STC and control signals DAC are generated in n groups corresponding to the single line of digital cyan image pixel signals. If a group is generated from a pulse signal STC and a control signal DAC in accordance with a digital cyan image pixel signal, the control signal DAG changes with the binary values of the corresponding digital cyan image pixel signal. As shown in the timing chart in Fig. 15, the control signal DAC is output as the top pulse of the pulse width PWC when the digital cyan image pixel signal has a value 1 which corresponds to the pulse width of the pulse signal STC, while when the digital pixel value 0 of the image pixel signal is Control signal DAG is a down pulse.

At step 1308 , the n bimetal elements R _{n are} optionally switched on in accordance with the n groups of pulse signals STC and control signals DAG. Only with a binary value 1 of the digital cyan image pixel signal is the corresponding transistor 72 of the pulse width PWC of the pulse signal STC switched on, so that the corresponding bimetal element R _{n is} fed electrically.

At step 1309 it is checked whether a predetermined very short time has elapsed in which the bimetallic element R _{n has been} heated to the temperature between the glass transition temperatures T ₁ and T ₂ . After the predetermined time, control passes to step 1310 where the solenoid 40 is turned on with the driver circuit 66 so that the thermal printhead assembly 34 is pivoted from the non-printing position ( Fig. 3) to the printing position, thereby heating the bimetallic elements R _n generate cyan pixels along a first single line on the microcapsule layer 14 of the substrate 10 .

At step 1311 , it is checked whether a predetermined very short time has elapsed in which the development of the cyan pixels has definitely been completed. After the predetermined time has passed, control transfers to step 1312 , where the solenoid 40 is turned off by the driver circuit 66 so that the thermal printhead assembly 34 is pivoted from the printing position to the non-printing position ( Fig. 3). Then, in step 1313, the selective activation of the bimetal elements R _{n is} interrupted.

At step 1314 it is checked whether the counter N contains the value 2. If it has not yet reached it, control goes to step 1315 , in which the counter reading is increased by 1. Control then returns to step 1306 .

At step 1306 , if the counter reading is 1, a further single line of digital single-color image pixel signals of the first single line of the color image pixel signals is retrieved from the memory 60 with the printer controller 56 . Since N = 1 in this state, these fetched digital single-color image pixel signals are assigned to the color magenta. Then, at step 1307, pulse signals STM and control signals DAM are generated in n groups corresponding to the single line of digital magenta image pixel signals. If a group of a pulse signal STM and a control signal DAM is generated in accordance with a digital magenta image pixel signal, the control signal DAM changes with the binary values of the digital magenta image pixel signal. As the timing chart in Fig FIG. 16, the STEU ersignal DAM as a top pulse is output with the pulse width of PWM the pulse signal STM which is greater than the pulse width PWC of the pulse signal STC when the digital magenta image pixel signal has the value 1. However, if it has the value 0, the control signal DAM remains at a low level.

At step 1308 , the n bimetallic elements R _{n are} selectively turned on in accordance with the n groups of pulse signals STM and control signals DAM. Only if the digital magenta image pixel signal has the value 1 is a transistor 72 corresponding to the pulse width PWM of the pulse signal STM switched on, so that the bimetallic element R _n assigned to it is fed electrically.

At step 1309 it is checked whether a predetermined very short time has elapsed in which the switched-on bimetal element R _{n has been} heated to the temperature between the glass transition temperatures T ₂ and T ₃ . If this time has elapsed, control proceeds to step 1310 , in which the electromagnet 40 is switched on with the driver circuit 66 , so that the thermal print head arrangement 34 is pivoted from the non-printing position ( FIG. 3) to the printing position and the heated bimetal elements R _n produce 10 magenta pixels along the first individual line on the microcapsule layer 14 of the substrate.

At step 1311 , it is checked whether a predetermined very short time has elapsed in which the development of the magenta pixels is safely completed. After the predetermined time has elapsed, control transfers to step 1312 , where the solenoid 40 is turned off with the driver circuit 66 so that the thermal printhead assembly 34 is pivoted from the printing position to the non-printing position ( Fig. 3). Then, at step 1313, the selective turning on of the bimetal elements R _{n is} interrupted.

At step 1314 , it is checked whether the counter N has the content 2. If the counter reading 2 has not yet been reached, control goes to step 1315 , in which the content is increased by 1. Control then returns to step 1306 .

At step 1306 , the remaining single line of digital single-color image pixel signals of the first single line of color image pixel signals is retrieved from the memory 60 with the printer controller 56 when the count 2 is reached. In this state (N = 2), the retrieved digital single-color image pixel signals are assigned to the color yellow. Then, at step 1307, pulse signals STY and control signals DAY are generated in n groups corresponding to the single line of digital yellow image pixel signals. If a group with a pulse signal STY and a control signal DAY is generated in accordance with a digital yellow image pixel signal, the control signal DAY changes with the binary values of the digital yellow image pixel signal. As the timing chart in Fig. 17 shows the Steuersi gnal DAY as a top pulse, the pulse width PWY outputted longer than the pulse width of the pulse signal PWM STM when the digital yellow image-pixel signal has the value 1. But if it has the value 0, the control signal DAY is kept at a low level.

At step 1308 , n bimetal elements R _n corresponding to the n groups of pulse signals STY and control signals DAY are electrically fed. Only if the digital yellow image pixel signal has the value 1 is a corresponding transistor 72 switched on during the pulse width PWY of the pulse signal STY, so that the bimetallic element R _n assigned to it is fed electrically.

At step 1309 , it is checked whether a predetermined very short time has elapsed in which the switched-on bimetal element R _{n has been} heated to the temperature between the glass transition temperature T ₃ and the upper limit temperature T _UL . After the predetermined time has elapsed, control transfers to step 1310 , where the solenoid 40 is turned on with the driver circuit 66 so that the thermal printhead assembly 34 is pivoted from the non-printing position ( Fig. 3) to the printing position, causing the heated bimetallic elements R _n Develop yellow pixels along the first individual line on the microcapsule layer 14 of the substrate 10 .

At step 1311 , it is checked whether a predetermined very short time has elapsed in which the development of the yellow pixels has been safely completed. After the predetermined time has elapsed, control goes to step 1312 , in which the solenoid 40 is turned off with the driver circuit 66 so that the thermal printhead assembly 34 is pivoted from the printing position to the non-printing position ( Fig. 3). Then at step 1313, the selective activation of the bimetal elements R _{n is} interrupted.

At step 1314 , it is checked whether the content of the counter N has the value 2. In this state (N = 2), control goes to step 1316 , in which the electric motor 64 is actuated so that the substrate 10 is transported by one step corresponding to a line. It is then checked at step 1314 whether the content of the counter L has the value SL which corresponds to the sum of individual lines of color image pixel signals corresponding to a field of digital color image pixel signals. If L <SL, control transfers to step 1318 , where the content of counter L is incremented by 1, after which it returns to step 1306 . The above-described line-by-line color printing is repeated in accordance with the successive single lines of digital color image pixel signals until the content of the counter L has reached the level SL.

If the counter L has reached the status SL in step 1317 , that is, all line-by-line color prints have been completed, control goes to step 1319 , in which the electric motor 64 is actuated so that the substrate 10 with the printed color image is output from the printer. Then it is checked whether another printing operation is to be performed. If so, control returns to step 1301 . If no further printing is to be carried out, the routine is ended.

Fig. 18 shows a further substrate 74, which is used in a second embodiment of an image generation. This substrate 74 is constructed similarly to the substrate 10 shown in FIG. 1. It consists of a sheet of paper 76 , a micro-capsule layer 78 and a transparent protective film 80 on the micro-capsule layer 78 . Similar to the substrate 10 , the microcapsule layer 78 consists of three types of microcapsules, namely first microcapsules 82 C with cyan dye, second microcapsules 82 M with magenta dye and third microcapsules 82 Y with yellow dye. These microcapsules 82 C, 82 M and 82 Y are evenly distributed in the microcapsule layer 78 .

As a graph shown in Fig. 19 shows, the substrate 74 compared to the substrate 10 has the difference that the synthetic resin of the cyan microcapsules 82 C has a continuous curve of the coefficient of elasticity versus temperature. The synthetic resin of the magenta microcapsules 82 M has a dash-dotted course of the elasticity coefficient. The synthetic resin of the yellow microcapsules 82 Y has a double dash-dotted curve of the elasticity coefficient.

The resin of the cyan microcapsules 82 C has a glass transition temperature T ₁ and loses its rubber elasticity when it is heated to a temperature T ₄ , whereby it is thermally melted or plasticized. The resin of the magenta microcapsules 82 M has a glass transition temperature T ₂ and loses its rubber elasticity when heated to a temperature T ₆ , whereby it is thermally melted or plasticized. The synthetic resin of the yellow microcapsule 82 Y has a glass transition temperature T ₃ and loses its rubber elasticity when heated to a temperature T ₅ , as a result of which it is thermally melted or plasticized.

As the graphic shown in FIG. 19 shows, the wall of the cyan microcapsules 82 C is compacted and broken at a crushing pressure between a critical crushing pressure P ₃ and an upper limit value P _UL if it has a temperature between the glass transition temperatures T ₁ and T ₂ Has. Similarly, the wall of the magenta microcapsule 82 M is compacted at a crushing pressure between the critical crushing pressure P ₂ and the critical crushing pressure P ₃ and broken when it has a temperature between the glass transition temperatures T ₂ and T ₃ , and the wall of the yellow microcapsules 82 Y is compacted and broken at a breaking pressure between the critical breaking pressure P ₁ and the critical breaking pressure P ₂ if it has a temperature between the glass transition temperature T ₃ and the plasticizing temperature T ₄ .

Furthermore, the walls of the cyan and magenta microcapsules 82 C and 82 M are compacted and broken at a breaking pressure between the critical breaking pressure P ₃ and the upper limit pressure P _UL when they have a temperature between the glass transition temperatures T ₂ and T ₃ . The walls of the magenta and yellow microcapsules 82 M and 82 Y are broken and compacted at a crushing pressure between the critical crushing pressure values P ₂ and P ₃ if they have a temperature between the glass transition temperature T ₃ and the plasticizing temperature T ₄ . The walls of the cyan and yellow microcapsules 82 C and 82 Y are melted or slightly broken and compacted at a crushing pressure between a critical crushing pressure P ₀ and the critical crushing pressure P ₁ when they reach a temperature between the plasticizing temperatures T ₅ and T _{6 have} yellow and magenta. In addition, the walls of the cyan, magenta and yellow microcapsules 82 C, 82 M and 82 Y are thermally melted or easily broken and compacted at a crushing pressure between the critical crushing pressure P ₃ and the upper limit P _UL when the cyan -, The magenta and yellow microcapsules 82 C, 82 M and 82 Y have at least the plasticizing temperature T ₄ .

By suitably choosing a heating temperature and a breaking pressure for the substrate 74 , it is therefore possible to selectively melt and / or break the cyan, magenta and yellow microcapsules 82 C, 82 M, 82 Y.

Fall the selected heating temperature and the crushing pressure z. B. in the hatched cyan development area C ( Fig. 19), which is defined by a temperature between the glass transition temperatures T ₁ and T ₂ and by a pressure between the critical refractive pressure P ₃ and the upper limit value P _UL , only the 82 C cyan microcapsules are compacted and broken, thereby developing the cyan color. If the selected heating temperature and the crushing pressure fall within the hatched magenta development area M, which is defined by a temperature between the glass transition temperatures T ₂ and T ₃ and by a pressure between the critical crushing pressure values P ₂ and P ₃ , only the magenta microcapsules become 82 M compacted and broken, which develops the color magenta. If the selected heating temperature and the crushing pressure fall within the hatched yellow development area Y, which is defined by a temperature between the glass transition temperature T ₃ and the plasticizing temperature T ₄ and by a pressure between the crushing pressure values P ₁ and P ₂ , then only the yellow -Microcapsules 82 Y compacted and broken, which develops the color yellow.

Fall the selected heating temperature and the crushing pressure in a hatched blue development area BE, which is defined by a temperature between the glass transition temperatures T ₂ and T ₃ and by a pressure between the critical refractive pressure P ₃ and the upper limit pressure P _UL , so the 82 C and 82 M cyan and magenta microcapsules are compacted and broken, thereby developing the color blue. If the selected heating temperature and the crushing pressure fall within a hatched red development area R, which is defined by a temperature between the glass transition temperature T ₃ and the plasticizing temperature T ₄ and by a pressure between the crushing pressure values P ₂ and P ₃ , the magenta and the yellow microcapsules 82 M and 82 Y compacted and broken, thereby developing the color red. If the selected heating temperature and the crushing pressure fall into a hatched green development area G, which is defined by a temperature between the plasticizing temperatures T ₅ and T ₆ and by a pressure between the critical crushing pressure values P ₀ and P ₂ , the cyan and the yellow micro capsules 82 C and 82 Y are thermally melted or slightly broken, thereby developing the color green. If the selected heating temperature and the crushing pressure fall into a hatched black development area BK, which is defined by a temperature between the plasticizing temperatures T ₄ and T ₆ and by a pressure between the critical crushing pressure P ₃ and the upper limit pressure P _UL , then the Cyan, magenta and yellow microcapsules 82 C, 82 M and 82 Y are thermally melted and / or slightly broken, thereby developing the color black.

Thus, if the selection of a heating temperature and a refractive pressure for the substrate 74 is controlled in accordance with the digital color image pixel signals, namely the digital cyan image pixel signals, the digital magenta image pixel signals and the digital yellow image pixel signals, it is possible to do so on the substrate 74 digital color image pixel signals to generate a multicolor image.

In the first embodiment of the image formation, three printing operations must be carried out before a single line of a color image is obtained on the micro capsule layer 14 of the substrate 10 . These are a cyan print for developing cyan pixels, a magenta print for developing stomach-colored pixels and a yellow print for developing yellow pixels corresponding to a single line of digital cyan, magenta and yellow image pixel signals.

In the second exemplary embodiment of the image forming device with the substrate 74 , a single line of a color image can be printed on the microcapsule layer 78 of the substrate 74 with the line printer according to FIGS. 6 and 7. For this purpose, the bimetallic elements R _n and the control circuit board 52 must be modified.

First, according to the graphic shown in FIG. 19, each bent bimetallic element R _n is modified so that it has a linear pressure / temperature characteristic TP that extends through all color development areas C, BE, M, R, Y, G and BK ( FIG . 19) runs. On the other hand, the control circuit board 52 is modified in the manner shown in FIG. 20. The selective switching on of the n bimetallic elements R ₁ to R _n is controlled by n groups of pulse signals ST and control signals DA, which are output by the printer controller 56 to the driver circuit 68 .

In Figs. 21 and 22 is a print operation of the Druckersteue tion 52 illustrates for the second embodiment of the image forming means the flow chart provided and will be described in the following.

At step 2101 , it is checked whether a single field of image pixel signals of the colors cyan, magenta and yellow is contained in the memory 60 . If this is confirmed, control goes to step 2102 , in which the electric motor 64 is actuated in such a way that a substrate 74 is transported into a printing start position.

At step 2103 , it is checked whether the substrate 74 has reached the printing start position, ie whether it is in the printing position. If it is confirmed, control transfers to step 2104 and the electric motor 64 is turned off. Then, at step 2105, the counter L is reset.

At step 2106 , a first single line of digital image pixel signals of the colors cyan, magenta and yellow is retrieved from the memory 60 with the printer controller 56 . Then, at step 2107, pulse signals ST and control signals DA are generated in n groups corresponding to the first single line of digital color image pixel signals. If a group is generated from a pulse signal ST and a control signal DA corresponding to a digital cyan image pixel signal, a digital magenta image pixel signal and a digital yellow image pixel signal, then the control signal DA changes according to a combination of binary values of these color image pixel signals, as shown in FIG. 23 is shown in a table and in FIG. 24 in a time diagram. In the table in Fig. 23, the color image pixel signals are designated CS, MS and YS.

As shown in Fig 23 and 24 show., The control signal DA as the top pulse HLP1 with the pulse width PW1 shorter than the pulse width SPW is it of the pulse signal ST testifies, if only the digital cyan image pixel signal CS has the value 1 and the üb membered digital Magenta and yellow image pixel signals MS and S have the value 0. If the digital cyan and magenta image pixel signals CS and MS have the value 1 and the yellow image pixel signal YS the value 0, the control signal DA is generated as the top pulse HLP2 with the pulse width PW2 longer than the pulse width PW1 of the top pulse HLP1 . If only the digital magenta image pixel signal MS has the value 1 and the other cyan and yellow image pixel signals CS and YS have the value 0, the control signal DA as the top pulse HLP3 with the pulse width PW3 becomes longer than the pulse width PW2 of the top -Pulses HLP2 generated. If the digital magenta and yellow image pixel signals MS and YS have the value 1 and the cyan image pixel signal CS has the value 0, then the control signal DA is generated as the top pulse HLP4 with the pulse width PW4 longer than the pulse width PW3 of the top pulse HLP3 . If only the digital yellow image pixel signal YS has the value 1 and the remaining cyan and magenta image pixel signals CS and MS have the value 0, then the control signal DA as the top pulse HLP5 with the pulse width PW5 becomes longer than the pulse width PW4 of the top pulse HLP4 generated. If the digital cyan and yellow image pixel signals CS and YS have the value 1 and the magenta image pixel signal MS have the value 0, then the control signal DA is generated as the top pulse HLP6 with the pulse width PW6 longer than the pulse width PW5 of the top pulse HLP5 . If the digital cyan, magenta and yellow image pixel signals CS, MS and YS have the value 1, then the control signal DA is generated as the top pulse HLP7 with the pulse width PW7 of the pulse signal ST and the pulse width SPW. If the digital cyan, magenta and yellow image pixel signals CS, MS and YS have the value 0, the control signal DA is kept at a low level.

At step 2108 , the n bimetal elements R _{n are} selectively electrically switched on in accordance with the n groups of pulse signals ST and control signals DA. If one of the n control signals DA is output as the top pulse HLP1, HLP2, HLP3, HLP4, HLP5, HLP6 or HLP7, a corresponding transistor 72 is switched on during the pulse width PW1 to PW7, so that the bimetallic element R _{n assigned to it is} switched on . By switching on during the pulse width PW1, the relevant bimetal element R _{n is} heated to a temperature in the cyan development area C. By turning on the Bimetallele ments R _n during the pulse width PW2, the bimetal element R _n is heated to a temperature in blue-developing region BE. By turning on the bimetal element R _n during the pulse width PW3, it is heated to a temperature in the magenta development area M. By switching on a bimetal element during the pulse width PW4, it is heated to a temperature in the red development area R. By turning on a bimetal element R _n during the pulse width PW5, it is heated to a temperature in the yellow development area Y. By turning on the bimetal element R _n during the pulse width PW6, it is heated to a temperature in the green development area G. By turning on a bimetal element R _n during the pulse width PW7, it is heated to a temperature in the black development region BK. If one of the control signals DA is kept at a low level, the corresponding transistor 72 is blocked, so that the corresponding bimetal element R _{n is} not switched on.

At step 2109 , it is checked whether a predetermined short time has elapsed in which the switched-on bimetallic elements R _{n have been} heated to temperatures which are defined by the color development regions C, BE, M, R, Y, G and BK. When the predetermined time has elapsed, the control proceeds to step 2110 in which the solenoid 40 is turned on to the driver circuit 66 so that the thermal print head assembly 34 is pivoted sition from the non-printing position to the Druckpo and the heated bimetal elements R _n colors Develop cyan, blue, magenta, red, yellow, green, and black along a first single line in the microcapsule layer 78 on the substrate 74 .

At step 2111 , a check is made to see if a predetermined short time has elapsed in which the development of the cyan pixels is safely completed. If this time has expired, control goes to step 2112 , in which the electromagnet 40 is switched off with the driver circuit 66 , so that the thermal print head arrangement 34 is pivoted from the printing position into the non-printing position. Then, at step 2113, the selective turning on of the bimetallic elements R _{n is} interrupted.

At step 2114 , the electric motor 64 is operated so that the substrate 74 is transported one step by one line. It is then checked at step 2115 whether the content of the counter L has reached the level SL, which corresponds to the sum of the individual lines of color image pixel signals corresponding to a field of digital color image pixel signals. If L <SL, control transfers to step 2116 , where the contents of counter L are incremented by 1, after which control returns to step 2106 . The line-by-line color printing described above is repeated in accordance with the successive individual lines of digital color image pixel signals until the content of the counter L has reached the level SL.

In step 2115 , control goes to step 2117 when the content of the counter L has reached the level SL, that is, when all line-by-line printing operations have been completed. The electric motor 64 is actuated so that the substrate 74 with the color image on it is output from the printer. Then it is checked whether another printing operation is to be performed. If so, control returns to step 2101 . If no further printing operation is required, the routine is ended.

A leuco pigment can be used as the dye for the microcapsules. This does not in itself produce pigmentation, ie it is colorless or transparent and does not produce a single color until it chemically reacts with a color developer. In this case, the color developer is contained in the binder which forms part of the microcapsule layer 14 or 78 .

With the above image-forming devices, single-color images can also be generated instead of multi-color images. Then the respective microcapsule layer 14 or 78 consists of only one type of microcapsule, the microcapsules of which, for. B. are filled with black dye.

Claims (6)

1. imaging system with
a substrate with a base, a microcapsule layer with at least one type of microcapsule, the microcapsules of which are filled with a dye,
wherein the at least one type of microcapsule has a pressure / temperature characteristic such that the dye escapes from the microcapsules when squeezed and broken at a predetermined pressure and temperature,
and with a pressure / temperature generating unit with a printing counter position, a thermal printhead arrangement with at least one of the printing oppositely assigned bent bimetallic element such that the substrate can be guided between the printing counter and the thermal printhead arrangement, and with an electrical feed system that the at least one bent Bimetallic element electrically heated according to imaging data, the bimetallic element depending on the electrical heating changes its assignment to the printed matter such that a pressure exerted on the printed matter with it becomes equal to the predetermined pressure when it is heated to the predetermined temperature. 2. Imaging system with
a substrate with a base, a microcapsule layer with at least two types of microcapsules, the microcapsules of which are each filled with a dye specific for each microcapsule,
wherein the types of microcapsules each have a pressure / temperature characteristic such that the dye emerges from the microcapsules upon squeezing and breaking at a predetermined pressure specific to each type of microcapsule and a predetermined temperature specific to each type of microcapsule,
and with a pressure / temperature generating unit with a printing counter position, a thermal printhead arrangement with at least one of the printing oppositely assigned bent bimetallic element such that the substrate can be guided between the printing counter and the thermal printhead arrangement, and with an electrical feed system that the at least one bent Bimetallic element electrically heated according to imaging data, the bimetallic element depending on the electrical heating changes its assignment to the printed matter such that a pressure exerted on the printed matter with it becomes equal to the predetermined pressure when it is heated to the predetermined temperature. 3. Imaging system according to claim 1 or 2, characterized in that that the at least one curved bimetal element is designed such that it increases its distance from the printed object with increasing electrical Heating increased. 4. Imaging system according to one of the preceding claims, since characterized in that the thermal print head assembly between egg ner first position in which the at least one curved bimetal element exerts negligible pressure on the platen, and one second position, in which the at least one curved bimetallic element exerts pressure on the platen, is movable and from which it most to the second position after heating to its predetermined temperature rature is moved. 5. Imaging system according to one of the preceding claims, since characterized in that the thermal print head assembly several ge Includes curved bimetallic elements that form a row next to each other the, and that the platen is designed as a rotatable printing roller and is arranged parallel to the line. 6. Imaging system according to claim 5, characterized in that the curved bimetal elements selectively according to a single line of the Image information data can be heated electrically.